Survival in the presence of antifungals: genome-wide expression profiling of Aspergillus niger in response to sublethal concentrations of caspofungin and fenpropimorph

Microbiologi

The cell wall of the filamentous fungus Aspergillus niger

Fungi are a very successful species and are distributed worldwide. However, the presence of fungi is not always desired. Filamentous fungi can grow on living or dead organic material and even inside the host. Current methods to prevent fungal growth are insufficient, causing fatality after fungal infections or loss of crops. The cell wall of a fungus is an intriguing component. It protects the cell from the harsh environment and determines the shape of the cell. Hence the cell wall is an essential component to the cell and provides an attractive target for antifungals. Additionally, the cell wall contains components only found in fungi, and the target is a desirable target as it is exposed on the outside of the cell. Currently, little is known about the cell wall of filamentous fungi. In order to design new or improved antifungal compounds, a better understanding of the fungal cell wall and of its adaptation to various conditions is required. In this thesis, we have used Aspergillus niger as a model filamentous fungus to study the biosynthesis of the fungal cell wall. The cell wall is a highly dynamic structure and able to adapt to various changes, either developmental (e.g. mating, growth, budding, branching and sporulation), environmental (e.g. heat, pH, osmolarity, chemical compounds), or genetic (e.g. mutations in cell-wall related genes). In chapter 1 an overview is presented of the current state of knowledge about the fungal cell wall. The architecture, biosynthesis and the remodeling are discussed in this chapter. The response of our model fungus A. niger to chemical induced cell wall stress is described in chapter 2. The fluorescent brightener Calcofluor White (CFW) was used to induce cell wall stress. We show that A. niger, like Saccharomyces cerevisiae, responds to cell wall stress by an increase of chitin deposition in the cell walls. This increase in chitin, a structural cell wall polymer, was accompanied by an increased transcription level of gfaA. It was also shown that this mechanism is not only limited to A. niger but is also observed in other filamentous fungi like the plant pathogenic fungus Fusarium oxysporum and the food spoilage fungus Penicillium chrysogenum. It is further shown that gfaA is an essential gene and the deletion strain can be rescued by addition of glucosamine. In chapter 3, a family of five 1,3-__-D-glucan synthase encoding genes is described. The expression of these genes during various types of cell wall stress was monitored and it was found that the expression of agsA and agsE was induced. The induction of an 1,3-__-D-glucan synthase encoding gene after cell wall stress was also observed in P. chrysogenum. The deletion of agsA led to an increased sensitivity towards CFW. While in chapter 2 and 3 changes in expression levels of genes encoding proteins involved in cell wall biosynthesis are described, the mechanism behind the induction of cell wall stress responsive genes is described in chapter 4. A promoter deletion study combined with an in silico analysis indicated that the induction of agsA in response to cell wall stress is dependent on a putative Rlm1p binding site in its promoter. Therefore a gene, named rlmA encoding for a MADS-box transcription factor was isolated from A. niger after database searches. The role of this gene in the induction of agsA and gfaA after CFW stress was investigated. A deletion of the rlmA gene was constructed and this resulted in an increased sensitivity towards cell wall disturbing compounds. In S. cerevisiae an important part of the response towards cell wall threatening conditions is the up-regulation of GPI-anchored cell wall proteins. In chapter 5 the isolation and characterisation of an HF-extractable cell wall protein from A. niger, named CwpA, is described. It was shown by simple fractionation experiments that the protein was mainly present in the cell wall fraction. Deletion of cwpA resulted in an increased sensitivity towards CFW suggesting a structural role for CwpA. Chapter 6 describes a novel method for the identification of cell wall mutants. The mutants are first selected based on their compensatory reaction (induction of agsA) and subsequenly subjected to various secondary screens, to confirm an altered cell wall integrity. Four out of 240 mutants with induced agsA expression levels, named miaA-D, were selected for complementation. All four mutants were complemented by cosmids. Further subcloning experiments are underway to identify the mutated genes. In chapter 7 a GFP-based reporter system is described. The system allows the rapid screening of compounds to see if they trigger the cell wall integrity pathway and thereby induce the PagsA(-H2B)-GFP reporter. The method has been evaluated towards various putative antifungal compounds and is a promising tool for the identification of new cell wall related antifungal compounds. In conclusion, this thesis provides evidence for the existence of a cell wall remodeling mechanism in filamentous fungi and in particular A. niger. Also, signal transduction pathway components were identified by which cell wall weakening is sensed and transduced into a transcriptional response. Additionally, a cell wall stress reporter system was developed to identify new cell wall related antifungal targets and to identify cell wall related antifungal compounds.Technology foundation STWUBL - phd migration 201

The cell wall of the filamentous fungus Aspergillus niger

Fungi are a very successful species and are distributed worldwide. However, the presence of fungi is not always desired. Filamentous fungi can grow on living or dead organic material and even inside the host. Current methods to prevent fungal growth are insufficient, causing fatality after fungal infections or loss of crops. The cell wall of a fungus is an intriguing component. It protects the cell from the harsh environment and determines the shape of the cell. Hence the cell wall is an essential component to the cell and provides an attractive target for antifungals. Additionally, the cell wall contains components only found in fungi, and the target is a desirable target as it is exposed on the outside of the cell. Currently, little is known about the cell wall of filamentous fungi. In order to design new or improved antifungal compounds, a better understanding of the fungal cell wall and of its adaptation to various conditions is required. In this thesis, we have used Aspergillus niger as a model filamentous fungus to study the biosynthesis of the fungal cell wall. The cell wall is a highly dynamic structure and able to adapt to various changes, either developmental (e.g. mating, growth, budding, branching and sporulation), environmental (e.g. heat, pH, osmolarity, chemical compounds), or genetic (e.g. mutations in cell-wall related genes). In chapter 1 an overview is presented of the current state of knowledge about the fungal cell wall. The architecture, biosynthesis and the remodeling are discussed in this chapter. The response of our model fungus A. niger to chemical induced cell wall stress is described in chapter 2. The fluorescent brightener Calcofluor White (CFW) was used to induce cell wall stress. We show that A. niger, like Saccharomyces cerevisiae, responds to cell wall stress by an increase of chitin deposition in the cell walls. This increase in chitin, a structural cell wall polymer, was accompanied by an increased transcription level of gfaA. It was also shown that this mechanism is not only limited to A. niger but is also observed in other filamentous fungi like the plant pathogenic fungus Fusarium oxysporum and the food spoilage fungus Penicillium chrysogenum. It is further shown that gfaA is an essential gene and the deletion strain can be rescued by addition of glucosamine. In chapter 3, a family of five 1,3-__-D-glucan synthase encoding genes is described. The expression of these genes during various types of cell wall stress was monitored and it was found that the expression of agsA and agsE was induced. The induction of an 1,3-__-D-glucan synthase encoding gene after cell wall stress was also observed in P. chrysogenum. The deletion of agsA led to an increased sensitivity towards CFW. While in chapter 2 and 3 changes in expression levels of genes encoding proteins involved in cell wall biosynthesis are described, the mechanism behind the induction of cell wall stress responsive genes is described in chapter 4. A promoter deletion study combined with an in silico analysis indicated that the induction of agsA in response to cell wall stress is dependent on a putative Rlm1p binding site in its promoter. Therefore a gene, named rlmA encoding for a MADS-box transcription factor was isolated from A. niger after database searches. The role of this gene in the induction of agsA and gfaA after CFW stress was investigated. A deletion of the rlmA gene was constructed and this resulted in an increased sensitivity towards cell wall disturbing compounds. In S. cerevisiae an important part of the response towards cell wall threatening conditions is the up-regulation of GPI-anchored cell wall proteins. In chapter 5 the isolation and characterisation of an HF-extractable cell wall protein from A. niger, named CwpA, is described. It was shown by simple fractionation experiments that the protein was mainly present in the cell wall fraction. Deletion of cwpA resulted in an increased sensitivity towards CFW suggesting a structural role for CwpA. Chapter 6 describes a novel method for the identification of cell wall mutants. The mutants are first selected based on their compensatory reaction (induction of agsA) and subsequenly subjected to various secondary screens, to confirm an altered cell wall integrity. Four out of 240 mutants with induced agsA expression levels, named miaA-D, were selected for complementation. All four mutants were complemented by cosmids. Further subcloning experiments are underway to identify the mutated genes. In chapter 7 a GFP-based reporter system is described. The system allows the rapid screening of compounds to see if they trigger the cell wall integrity pathway and thereby induce the PagsA(-H2B)-GFP reporter. The method has been evaluated towards various putative antifungal compounds and is a promising tool for the identification of new cell wall related antifungal compounds. In conclusion, this thesis provides evidence for the existence of a cell wall remodeling mechanism in filamentous fungi and in particular A. niger. Also, signal transduction pathway components were identified by which cell wall weakening is sensed and transduced into a transcriptional response. Additionally, a cell wall stress reporter system was developed to identify new cell wall related antifungal targets and to identify cell wall related antifungal compounds

Expression of agsA, one of five 1,3-alpha-D-glucan synthease-encoding genes in Aspergillus niger, is induced in response to cell wall stress.

1,3-alpha-D-Glucan is an important component of the cell wall of filamentous fungi. We have identified a family of five 1,3-alpha-D-glucan synthase-encoding genes in Aspergillus niger. The agsA gene was sequenced and the predicted protein sequence indicated that the overall domain structure of 1,3-alpha-D-glucan synthases is conserved in fungi. Using RT-PCR and Northern blot analysis, we found that expression of the agsA gene and to a lesser extent also of agsE were induced in the presence of the cell wall stress-inducing compounds such as Calcofluor White (CFW), SDS, and caspofungin. Loss of agsA function did not result in an apparent phenotype under normal growth conditions but rendered the cells more sensitive to CFW. The induction of 1,3-alpha-D-glucan synthase-encoding genes in response to cell wall stress was not limited to A. niger, but was also observed in Penicillium chrysogenum. We propose that this response to cell wall stress commonly occurs in filamentous fungi

The cell wall stress response in Aspergillus niger involves increased expression of the glutamine: Fructose-6-phosphate amidotransferase-encoding gene (gfaA) and increased deposition of chitin in the cell wall

Perturbation of cell wall synthesis in Saccharomyces cerevisiae, either by mutations in cell wall synthesis-related genes or by adding compounds that interfere with normal cell wall assembly, triggers a compensatory response to ensure cell wall integrity. This response includes an increase in chitin levels in the cell wall. Here it is shown that Aspergillus niger also responds to cell wall stress by increasing chitin levels. The increased chitin level in the cell wall was accompanied by increased transcription of gfaA, encoding the glutamine: fructose-6-phosphate amidotransferase enzyme, which is responsible for the first and a rate-limiting step in chitin synthesis. Cloning and disruption of the gfaA gene in A. niger showed that it was an essential gene, but that addition of glucosamine to the growth medium could rescue the deletion strain. When the plant-pathogenic fungus Fusarium oxysporum and food spoilage fungus Penicillium chrysogenum were subjected to cell wall stress, the transcript level of their gfa gene increased as well. These observations suggest that cell wall stress in fungi may generally lead to activation of the chitin biosynthetic pathway. © 2004 SGM

A novel screening method for cell wall mutants in Aspergillus niger identifies UDP-galactopyranose mutase as an important protein in fungal cell wall biosynthesis

To identify cell wall biosynthetic genes in filamentous fungi and thus potential targets for the discovery of new antifungals, we developed a novel screening method for cell wall mutants. It is based on our earlier observation that the Aspergillus niger agsA gene, which encodes a putative a-glucan synthase, is strongly induced in response to cell wall stress. By placing the agsA promoter region in front of a selectable marker, the acetamidase (amdS) gene of A. nidulans, we reasoned that cell wall mutants with a constitutively active cell wall stress response pathway could be identified by selecting mutants for growth on acetamide as the sole nitrogen source. For the genetic screen, a strain was constructed that contained two reporter genes controlled by the same promoter: the metabolic reporter gene PagsA-amdS and PagsA-H2B-GFP, which encodes a GFP-tagged nuclear protein. The primary screen yielded 161 mutants that were subjected to various cell wall-related secondary screens. Four calcofluor white-hypersensitive, osmotic-remediable thermosensitive mutants were selected for complementation analysis. Three mutants were complemented by the same gene, which encoded a protein with high sequence identity with eukaryotic UDP-galactopyranose mutases (UgmA). Our results indicate that galactofuranose formation is important for fungal cell wall biosynthesis and represents an attractive target for the development of antifungals. Copyright © 2008 by the Genetics Society of America

Peroxicretion: A novel secretion pathway in the eukaryotic cell

Background: Enzyme production in microbial cells has been limited to secreted enzymes or intracellular enzymes followed by expensive down stream processing. Extracellular enzymes consists mainly of hydrolases while intracellular enzymes exhibit a much broader diversity. If these intracellular enzymes could be secreted by the cell the potential of industrial applications of enzymes would be enlarged. Therefore a novel secretion pathway for intracellular proteins was developed, using peroxisomes as secretion vesicles. Results: Peroxisomes were decorated with a Golgi derived v-SNARE using a peroxisomal membrane protein as an anchor. This allowed the peroxisomes to fuse with the plasma membrane. Intracellular proteins were transported into the peroxisomes by adding a peroxisomal import signal (SKL tag). The proteins which were imported in the peroxisomes, were released into the extracellular space through this artificial secretion pathway which was designated peroxicretion. This concept was supported by electron microscopy studies. Conclusion: Our results demonstrate that it is possible to reroute the intracellular trafficking of vesicles by changing the localisation of SNARE molecules, this approach can be used in in vivo biological studies to clarify the different control mechanisms regulating intracellular membrane trafficking. In addition we demonstrate peroxicretion of a diverse set of intracellular proteins. Therefore, we anticipate that the concept of peroxicretion may revolutionize the production of intracellular proteins from fungi and other microbial cells, as well as from mammalian cells.BiotechnologyApplied Science